A throttle body may have a main bore for supplying a fuel and air mixture to an engine. A throttle valve head may be received in the main bore and movable between idle and wide open positions to control fluid flow through the main bore. A main fuel outlet and a boost venturi may open to the main bore and a flow directing feature may alter the velocity and/or direction of fluid flow in the main bore relative to the fuel outlet or boost venturi. The flow directing feature may be carried by the body, the throttle valve head, or the boost venturi.
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9. A throttle body, comprising:
a body having a main bore from which a fuel and air mixture is discharged for use by an engine, the main bore having an inlet side into which air flows into the main bore and an outlet side from which air and fuel exit the main bore;
a throttle valve head carried by the body and moveable between an idle position and an open position to control at least some fluid flow through the main bore;
a boost venturi open to the main bore and arranged between the throttle valve head and the outlet side of the main bore; and
a flow directing feature to alter at least one of the velocity or direction of at least a portion of the fluid that flows in the main bore and relative to the boost venturi, the flow directing feature being carried by the body separate from the throttle valve head and the boost venturi, wherein the flow directing feature extends fully across the main bore.
13. A throttle body, comprising:
a body having a main bore from which a fuel and air mixture is discharged for use by an engine, the main bore having an inlet side into which air flows into the main bore and an outlet side from which air and fuel exit the main bore;
a throttle valve head carried by the body and moveable between an idle position and an open position to control at least some fluid flow through the main bore;
a boost venturi open to the main bore and arranged between the throttle valve head and the outlet side of the main bore;
a flow directing feature to alter at least one of the velocity or direction of at least a portion of the fluid that flows in the main bore and relative to the boost venturi, the flow directing feature being carried by the body separate from the throttle valve head and the boost venturi; and
a tube extending from the main body to the boost venturi and defining a fuel passage having a fuel outlet within the boost venturi.
1. A throttle body, comprising:
a body having a main bore from which a fuel and air mixture is discharged for use by an engine, the main bore having an inlet side into which air flows into the main bore and an outlet side from which air and fuel exit the main bore;
a throttle valve head carried by the body and moveable between an idle position and an open position to control at least some fluid flow through the main bore;
a boost venturi open to the main bore and arranged between the throttle valve head and the outlet side of the main bore; and
a flow directing feature to alter at least one of the velocity or direction of at least a portion of the fluid that flows in the main bore and relative to the boost venturi, the flow directing feature being carried by the body separate from the throttle valve head and the boost venturi, and wherein the flow directing feature is arranged downstream of the throttle valve head and upstream of an inlet of the boost venturi, where downstream and upstream are with regard to a direction of fluid flow through the main bore.
2. The throttle body of
3. The throttle body of
4. The throttle body of
5. The throttle body of
6. The throttle body of
7. The throttle body of
8. The throttle body of
10. The throttle body of
11. The throttle body of
12. The throttle body of
14. The throttle body of
15. The throttle body of
16. The throttle body of
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This application is a divisional of U.S. patent application Ser. No. 16/331,394 filed Mar. 7, 2019, which is a national phase of PCT/US2017/049837 filed Sep. 1, 2017 and claims the benefit of U.S. Provisional Application Ser. No. 62/385,673 filed on Sep. 9, 2016. The entire contents of these priority applications are incorporated herein by reference in their entireties.
The present disclosure relates generally to a throttle body for providing a fuel and air mixture to an engine.
A variety of fuel injection throttle body configurations are known for supplying a fuel and air mixture to an internal combustion engine to support its operation in which a liquid gasoline fuel is injected into a main bore at a relatively high pressure typically in the range of 6 to 40 psi and sometimes up to 80 psi or more above ambient atmospheric pressure or 21 to 55 psi or more to facilitate mixing or dispersion of the liquid fuel in the fuel and air mixture supplied to the engine. To control the rate of flow of the mixture to the engine, a throttle valve with a planar valve head in the main bore is carried on a shaft that is rotated to move the valve head between an idle position, associated with low speed and/or low load engine operation, and a wide open or fully open position, associated with high speed and/or high load engine operation. Typically a fuel pump and pressure regulator supplies liquid fuel at this high pressure to a fuel metering valve or injector which is opened and closed by an electronic controller such as a microcontroller at defined times to discharge the appropriate quantity of fuel into the main bore for the current operating condition of the engine. Typically the fuel metering valve is located upstream of the throttle body valve head or much further downstream of the throttle body and proximate to the engine fuel intake port or engine intake valve pocket.
In at least some implementations a throttle body may have a main bore from which a fuel and air mixture is supplied to the engine, a throttle valve head movable between an idle and a wide open position to control at least some flow through the main bore to the engine, a main fuel outlet open to the main bore, and a flow directing feature altering at least one of the velocity or direction of at least a portion of the fluid that flows in the main bore relative to the main fuel outlet. In at least some implementations fuel flow through the main fuel outlet may be electronically controlled. In at least some implementations the flow directing feature may direct a portion of air flowing in the main bore toward the main fuel outlet. In at least some implementations the main fuel outlet discharges fuel into a boost venturi. In some implementations the boost venturi may preferably be located downstream of the throttle valve head. In some implementations, a main fuel outlet discharges fuel into the boost venturi and the flow directing feature directs a portion of air flowing in the main bore into the boost venturi. In at least some implementations, the flow directing feature may be carried by at least one of the throttle valve head, body and the boost venturi. In at least some implementations the flow directing feature may include a non-planar portion of or carried by the throttle valve head. In at least some implementations, one or more projections may extend from the valve head. In at least some implementations, the flow directing feature may include a channel through which air flowing in the main bore is directed toward the boost venturi and in some implementations the channel may be centered about a plane that includes a center axis of the boost venturi.
The following detailed description of preferred embodiments and best mode will be set forth with reference to the accompanying drawings, in which:
Referring in more detail to the drawings,
The main bore 14 may have any desired shape including (but not limited to) a constant diameter cylinder or a venturi shape wherein the inlet 16 leads to a tapered converging portion that leads to a reduced diameter throat that in turn leads to a tapered diverging portion that leads to the outlet 18. The converging portion may increase the velocity of air flowing into the throat and create or increase a pressure drop in the area of the throat. Especially when a fuel injector or other metering device 20 is used and fuel is provided under some positive pressure, a straight cylindrical bore can be used as it provides less restriction to air flow compared to bores of non-uniform diameter or cross-sectional area, and the fuel flow provided through the control valve can be metered to match the air flow over a wide range of conditions.
In at least some implementations, a secondary venturi, sometimes called a boost venturi 21 may be located within the main bore 14 whether the main bore 14 has a venturi shape or not. The boost venturi 21 may have any desired shape, and as shown in
The throttle body 10 may include a throttle valve 48 carried by the main body 12 for adjusting the flow rate of the fuel and air mixture out of the throttle body 10. The throttle valve 48 includes a throttle shaft 50 and a throttle valve head 52 mounted, such as by one or more screws 54, to the throttle shaft 50. The throttle shaft 50 is rotatably carried by or relative to the body 12 and extends transversely across the main bore 14 to enable rotation of the throttle valve head 52 relative to the main bore. In at least some implementations, the throttle valve head 52 is defined by a flat disc commonly referred to as a butterfly valve head. The throttle valve 48 is rotated between an idle position and a wide open position, and may be operated at various positions in between those two positions. In the idle position, the throttle valve head 52 is substantially transverse to the axis 38 of the main bore 14, and may be rotated between about 3 and 20 degrees from a plane that is transverse to the axis 38. In this position, the throttle valve head 52 provides a maximum restriction to air flow out of the main bore 14, but allows sufficient air or fluid flow to support idle engine operation. In the wide open position of the throttle valve 48, shown in
The main fuel outlet 56 opens into or is otherwise communicated with the main bore 14 and is in communication with the fuel metering device 20 (e.g. a fuel injector or a fuel flow control valve) to enable fuel flow into the main bore 14. The fuel metering device may be carried by the body 12 and may provide a metered flow of fuel into a fuel passage leading to the fuel outlet 56. The main fuel outlet 56 may include a port which may be formed in the body 12 or defined by an insert assembled into the body, such as the rod 40 coupled to the boost venturi 21 which may be hollow and define a fuel passage. The main fuel outlet 56 may be located between the inlet and outlet sides 16, 18 of the main bore 14 and may be within or downstream of a narrower portion of the main bore (if provided) which acts as a venturi to increase flow velocity and decrease fluid pressure near the main fuel outlet 56. Of course, the main bore need not have a venturi portion or venturi shape, as noted above. In at least some implementations, the fuel outlet 56 and a center of the boost venturi (taken perpendicular to the boost venturi axis 36) may be located closer to the outlet 18 of the main bore than the inlet 16. The fuel outlet 56 may be a simple port open to the boost venturi passage 30, may be defined in a conduit or tube 40 extending into the boost venturi 21, and/or may include more than one opening or port open into the boost venturi or downstream thereof.
In one example shown in
To aid in directing air flow in the area of the main fuel outlet 56, a flow directing feature may be associated with, such as by being carried by, at least a portion of the throttle valve head 52. In the embodiment of
Also, as shown in
In addition to increasing fluid flow velocity near the main fuel outlet 56, the non-planar portion 60 of the throttle valve head 52 can also direct the air flow in the first section 61 away from the second section 63 to maintain and even promote separation of the fluid streams. In this regard, the non-planar portion 60 of the throttle valve head 52 may extend to or within 3 mm of the downstream edge 68 of the throttle valve head 52, and may serve to provide a more consistent stream of air to the inlet of the boost venturi 21 to enable some control over the fluid flow in and through the boost venturi over a wider range of throttle valve positions and engine operating conditions.
In addition to or instead of the non-planar portion 60 of the throttle valve head 52, a second flow directing feature 70 may be provided in the area of the boost venturi 21. This flow directing feature 70 may be separate from the throttle body main body 12 (e.g. not a restriction formed in the main bore 14) and is arranged to direct and control air flow in the area of the boost venturi or main fuel outlet if no boost venturi is provided. In the implementation shown in
As shown in
When used with a throttle valve head 52 having a non-planar portion 60, at least part of the projections 72 may extend along at least a portion of the non-planar portion 60 of the throttle valve head 52. Thus, both flow directing features 60, 70 work together in promoting a desired air flow through at least part of the main bore 14. As best shown in
In
While shown as extending within the first section 61 of the main bore 14 (i.e. a section including or aligned in the direction of air flow with the boost venturi 21), a flow directing feature may be used elsewhere in the throttle body 10. For example, the second side 66 of the throttle valve head 52 could include a flow directing feature arranged to direct flow out of the second section of the main bore and toward the boost venturi or otherwise as desired. As just one other example, fluid in the second section 63 could be directed away from the first section 61 to, for example, encourage mixing of an air stream with a fuel and air mixture downstream of the boost venturi. Further, while the offset or angled non-planar portion 60 of the throttle valve head 52 may be defined by a bend in the throttle valve head 52, it could be implemented in a thicker portion of the throttle valve head. The second side 66 of the throttle valve head 52 could be planar (e.g. not include a bend) or even include an angled or ramped surface directed away from the first section 61 of the main bore 14. The throttle valve head 52 may be formed from any suitable material, such as various metals and plastics, with all features formed in one, integral piece of material, or from multiple pieces of material.
Further, as shown in
One or more flow directing features may also be formed on, carried by or associated with the boost venturi 21. In the examples shown in
Further, the throttle valve head 52 may include an opening 104 through which air flows when the throttle valve is in its first position (e.g. idle) and in positions between the first and second positions (e.g. up to 50% of throttle valve movement away from the idle position), as shown in
A throttle valve head 52 may be mounted off-center relative to the main bore 14 such that one of the two sections 61, 63 is larger than the other, as desired. In other words, a rotational axis 106 of the throttle valve shaft 50 does not intersect the axis 38 of the main bore 14. In at least some implementations, the main bore axis 38 may extend between the throttle valve shaft axis 106 and the boost venturi axis 36. Hence, when the throttle valve 48 is in its second or open position, more than half of the area of the main bore 14 may be open in the first section 61, and the flow directing features may then direct more air toward the fuel outlet and/or boost venturi. In at least some implementations, the throttle shaft axis 106 may be offset from the main bore axis 38 by between 0.5 mm to 6 mm (and as noted above this may make the first section 61 larger than the second section 63) for main bores having a diameter between 18 mm and 40 mm.
Further, a throttle valve head 52 may be provided with any one of, or any combination of, the various flow directing features described herein as well as modified flow directing features that persons of ordinary skill in the art will readily devise in view of the teachings herein. In other words, these features may be used separately or in any desired combination. Further, while various features were described that increase fluid flow velocity, flow directing features could also be provided that decrease a fluid flow velocity. Likewise, while certain features were described as promoting separation of two fluid flows, flow directing features like those disclosed herein could also be implemented to encourage mixing of fluid within the throttle body. Still further, the features discussed herein, separately or in any combination, could also be implemented on or associated with the throttle valve.
While representative flow directing features have been shown in these figures, many more shapes, sizes and orientations are possible; the illustrated implementations are not intended to limit the scope of the disclosure in any way. Further, the valve heads shown herein can be oriented in different ways/directions relative to the direction of air flow and need not be in the orientations shown in the drawings.
The flow directing features and boost venturi downstream of the throttle valve may, among other things, provide improved mixing of fuel and air in the main bore. Additionally, the throttle body so arranged may provide an improved pressure signal at the fuel outlet to improve engine operation during low speed and high load operating conditions that can cause engine lugging, provide a low cost system that provides fuel at relatively low pressure compared to higher pressure fuel injected systems, provide striation of air flows between the first and second sections of the main bore with the ability to provide more airflow in the first section and to the boost venturi if desired, control airflow and pressure signals at the fuel outlet to enhance management of the fuel and air mixture provided from the throttle body.
While the forms of the invention herein disclosed constitute presently preferred embodiments, many others are possible. For example, the flow directing features can have other shapes, orientations, locations and functions as would be appreciated by persons of ordinary skill in this art in view of this disclosure. It is not intended herein to mention all the possible equivalent forms or ramifications of the invention. It is understood that the terms used herein are merely descriptive, rather than limiting, and that various changes may be made without departing from the spirit or scope of the invention.
Roche, Bradley J., Galka, William E., Speirs, David L., Burns, Gary J., Sayers, Albert L.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Aug 28 2017 | BURNS, GARY J | WALBRO LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058834 | /0957 | |
Aug 28 2017 | GALKA, WILLIAM E | WALBRO LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058834 | /0957 | |
Aug 28 2017 | SAYERS, ALBERT L | WALBRO LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058834 | /0957 | |
Aug 28 2017 | SPEIRS, DAVID L | WALBRO LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058834 | /0957 | |
Aug 30 2017 | ROCHE, BRADLEY J | WALBRO LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058834 | /0957 | |
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